|Publication number||US7651459 B2|
|Application number||US 10/752,164|
|Publication date||Jan 26, 2010|
|Filing date||Jan 6, 2004|
|Priority date||Jan 6, 2004|
|Also published as||CA2552519A1, CA2552519C, EP1708787A2, EP1708787A4, EP1708787B1, US20050148808, WO2005067610A2, WO2005067610A3|
|Publication number||10752164, 752164, US 7651459 B2, US 7651459B2, US-B2-7651459, US7651459 B2, US7651459B2|
|Inventors||Allan Cameron, John A. MacNeill, Gregg Flender, Mark Edward Riehl|
|Original Assignee||Neuronetics, Inc.|
|Export Citation||BiBTeX, EndNote, RefMan|
|Patent Citations (98), Non-Patent Citations (13), Referenced by (7), Classifications (9), Legal Events (4)|
|External Links: USPTO, USPTO Assignment, Espacenet|
The present invention relates to a method and apparatus for precisely positioning a medical instrument with respect to a patient and, more particularly, to a positioning system and method for precisely and repeatably positioning a transcranial magnetic stimulation coil at the treatment position of a patient.
Current methods of placement and positioning of coils for Transcranial Magnetic Stimulation (TMS) studies are either manual methods or approaches designed for research that require expensive and complex imaging or computational systems to determine three dimensional spatial coordinates for positioning reference. These techniques have severe clinical limitations. The manual methods do not provide a convenient means for repeated and accurate placement, while the three dimensional spatial methods based on imaging modalities are expensive, time consuming, and not conducive to clinical use. A positioning technique for clinical use is desired that provides a simple way for the operator to perform repeated and accurate coil placement for TMS studies and treatments in a time-efficient and inexpensive manner.
In accordance with the conventional manual placement and position marking technique, a treatment position on the patient's head or a position used to find a treatment position, such as the patient's motor threshold position (MTP), is determined by moving the coil near a predicted area determined by patient anatomical landmarks until the desired motor response is achieved. The position is marked, for example, with an ink mark on the patient's head. In the case of using the TMS coil for treatment of depression, for example, the TMS therapy position is determined by moving the coil from the MTP along a line in the anterior direction a prescribed distance (a widely accepted distance is 5 cm). The Therapy Position (TXP) is then marked on the patient (e.g., with ink) so it can be easily found in subsequent therapy sessions.
The most common method of localization used for TMS studies is described by George et al. in “Daily Repetitive Transcranial Magnetic Stimulation (rTMS) Improves Mood in Depression,” NeuroReport, Vol. 6, No. 14, October 1995, pp. 1853-1856, and by Pascual-Leone et al. in “Rapid-Rate Transcranial Magnetic Stimulation of Left Dorsolateral Prefrontal Cortex in Drug-Resistant Depression,” The Lancet, Vol. 348, Jul. 27, 1996, pp. 233-237. Simply stated, in these methods the coil is first moved over the area of the left motor cortex until stimulation of the contralateral abductor pollicis brevis muscle (APB) is attained. This position is the motor threshold position (MTP) and is typically located on a line between the left auditory meatus (i.e. ear canal) and the vertex of the head, at a point about ½ to ⅔ of the distance to the vertex. In the case of excitatory stimulation of the left prefrontal cortex for the treatment of depression, for example, the TXP is located by starting at the MTP and moving 5 cm toward the midpoint between the tip of the nose and the nasion (protuberance just above the bridge of the nose). More details of techniques for determining the MTP are also described in related U.S. patent application Ser. No. 10/714,741, filed Nov. 17, 2003, the contents of which are incorporated herein by reference.
The shortcomings of such manual methods are that precisely determining the line from the MTP to the TXP is difficult, marks applied to the patient either wash off between treatment sessions (so they do not help with the next treatment session) or they do not wash off (which is cosmetically undesirable), the coil may not be comfortably held at the TXP throughout a therapy session, and the technique is highly operator dependent and not conducive to repeatable and accurate positioning.
The problem of applying marks to the patient has been addressed in the art by applying a swim cap or similar conformal headgear to the patient and marking the headgear rather than the patient. Of course, this approach requires careful registration of the headgear during subsequent therapy sessions, which is crude, imprecise, and highly operator dependent. Moreover, such an approach still requires accurate coil placement and a mechanism for holding the coil in place.
Complex Imaging/Computational Systems
The Brainsight™ System developed by Rogue Research, Inc. of Montreal, Canada and distributed by Magstim is complex and is designed primarily for research purposes. This system uses diagnostic images from MRI or PET systems to determine the spatial relationship between internal anatomy and external landmarks and then aligns to the external landmark for therapy or other studies requiring accurate localization. While this approach is useful for research purposes, it is highly impractical and complex and is thus not usable in general clinical practice. Moreover, such techniques have generally been used to overlay coordinate systems onto images and not for identifying particular treatment positions for specific therapies.
Robotic Arms for Holding TMS Coils
U.S. Pat. No. 6,266,556 and U.S. Patent Application No. 2003/0050527 include descriptions of methods in which a robotic arm is operatively coupled to the TMS coil for positioning the coil with respect to the patient and holding the coil in place during TMS treatment. A similar technique using a robotic arm for coil placement is also disclosed in U.S. Patent Application Nos. 2003/0004392 to Tanner et al. and 2003/0065243 to Tanner. These applications further disclose a technique for modeling the spatial structure of the patient's brain for determining the proper stimulation position using a stimulation model. While these techniques provide controlled movement and placement of the coil, they are quite expensive and do not provide for repeatable placement of the coil with respect to a particular patient's head in a clinical setting. As a result, the manual and/or complex imaging techniques described above must also be used for placement of the coil with respect to the patient.
Thus, the need for a simple, cost-effective and intuitive way to accurately and repeatably position the coil for TMS therapy in a clinical setting has not been met in the prior art. The present invention addresses this need.
The invention addresses the above-mentioned limitations in the prior art through use of a mechanical device that provides simple positioning of the patient's head and simple positioning of the TMS coil relative to a coordinate system of the patient's head once the head is positioned. The TMS coil is fixed at a treatment position in the coordinate system of the patient's head and the position in the coordinate system is recorded for use in subsequent clinical sessions. In an exemplary embodiment, the positioner assembly is a mechanical system that supports the weight of the TMS coil (approximately five pounds in the case of designs that use a ferromagnetic core material) and allows the operator to freely move the TMS coil to search for the treatment position and/or the patient's motor threshold position (MTP). Once the MTP is determined, the positioner assembly requires only a single adjustment of the magnet position to locate the treatment position (TXP) where the coil is locked in place for the duration of the TMS therapy. By recording the positions of the different adjustable components in the respective coordinate directions of the coordinate system of the patient's head, exact repositioning of the TMS coil for the patient during a subsequent clinical visit is made possible without use of expensive imaging equipment. Exemplary embodiments described herein illustrate a device for repeatably positioning a transcranial magnetic stimulation (TMS) coil with respect to a patient to receive treatment. The device of the invention includes three basic components, each of which is unique to the TMS art. A headset assembly accepts the patient's head and fixes its position, while a coil positioner assembly accepts the headset assembly and holds the headset assembly and the patient's head at a fixed position, controls positioning of the TMS coil within a coordinate system defined about the fixed position, and holds the TMS coil in place at a treatment position during treatment. An alignment strip applied at a position in registration with an anatomical landmark of the patient includes at least one registration mark for aligning the patient's head within the headset assembly. Each of these components working together permit the coil assembly to be located in coordinates with respect to the patient's head such that the treatment may be repeated during a subsequent visit by repeating the coordinates.
In the described exemplary embodiments, the patient's head is held in the headset assembly by quick release straps that permit the patient to be rapidly removed from the headset assembly and the coil positioner assembly in the event of an emergency or the pausing of a treatment. The coil positioner assembly also includes a sighting mechanism that aligns an anatomical landmark of the patient with the coil positioner assembly to define a pivot axis through the patient's nose. For example, the sighting mechanism may include a registration mark that may be aligned with a corner of the patient's eye. The coil positioner assembly may also include a gimbal mount that supports the TMS coil. A counterbalance for the gimbal arrangement and the weight of the coil may also be used to offset the weight that would be applied against the patient's head. The gimbal arrangement may further include a mechanism that adjusts a roll of the TMS coil so that the TMS coil may seat against the patient's head. On the other hand, the coil positioner assembly may include a ball and socket that supports the TMS coil in place of the gimbal mount.
The invention also includes numerous methods of using the elements of the invention to repeatably position a transcranial magnetic stimulation (TMS) coil with respect to a patient to receive treatment. For example, a first method in accordance with the invention comprises the steps of:
fixing the patient's head at a fixed position;
defining a coordinate system about the fixed position;
finding a treatment position on the patient for the TMS coil;
recording the coordinates of the treatment position in the coordinate system; and
mechanically supporting the TMS coil at the treatment position during treatment.
In an exemplary embodiment of this method, the step of fixing the patient's head at a fixed position includes the steps of:
placing the patient's head in a headset assembly having a cushion for accepting a back of the patient's head and alignment straps that restrain the patient's head in the nodding and left/right directions;
applying an alignment strip with a registration mark at a position on the patient so as to align the registration mark with an anatomical landmark of the patient;
wrapping a first of the alignment straps from a back of the patient's head over a crown of the patient's head to an alignment position on the alignment strip; and
wrapping a pair of lateral straps of the alignment straps from the back of the patient's head around the respective sides of the patient's head to alignment positions on the alignment strip so as to center the patient's face in the left/right direction in a mid-sagittal plane.
By way of example, the alignment strip may be applied to a forehead of the patient and the registration mark aligned with the patient's nose. In this case, the method may also include the step of adjusting a left/right position of the patient's head until the lateral straps have the same length at the registration mark on the alignment strap.
In accordance with the methods of the invention, the step of finding a treatment position may further comprise the steps of adjusting a first adjustment mechanism so as to adjust an angle of a left or right superior oblique plane with respect to the mid-sagittal plane and adjusting a second adjustment mechanism so as to adjust an anterior/posterior distance in the left or right superior oblique plane. When searching for a motor threshold position, for example, these first and second adjustment mechanisms may be adjusted so as to define a grid pattern of coordinates in respective left superior oblique planes at different angles to the mid-sagittal plane and different positions within each respective left superior oblique plane in an anterior/posterior direction until the treatment position and/or the motor threshold position is found. Once the motor threshold position is found, the treatment position for depression, for example, may be readily found by simply adjusting the second adjustment mechanism in the anterior direction within the left superior oblique plane by 5 cm or a distance that is a function of the size of the patient's head.
In accordance with another aspect of the invention, the step of fixing the patient's head at the fixed position comprises the step of placing the patient's head at an angle with respect to the horizontal that is optimized for patient comfort, cortical excitability, and so as to reduce the weight of the patient's head on the patient's shoulders. In an exemplary embodiment, the angle is approximately 30°-45° from the horizontal.
The above and other features and advantages will become apparent to those skilled in the art based on the following detailed description of the drawing figures, of which:
A detailed description of an illustrative embodiment of the present invention will now be described with reference to
The present invention is designed to position a TMS coil for treatment of central nervous system disease states using TMS therapies. While an exemplary embodiment of the invention is described with respect to the excitatory stimulation of the left prefrontal cortex for the treatment of depression, those skilled in the art will appreciate that the apparatus and techniques of the invention may be used to apply TMS therapies to many other central nervous system targets for the treatment of numerous other central nervous system diseases. For example, the positioning device of the invention may be used to position the TMS over the right prefrontal cortex of a patient for low frequency inhibitory stimulation in the treatment of depression. Those skilled in the art will further appreciate that the positioning device of the invention also may be used to position a TMS coil for the treatment of: epilepsy (above seizure locus), schizophrenia (at Wernicke's Area), Parkinson's Disease, Tourette's Syndrome, Amyotrophic Lateral Sclerosis (ALS), Multiple Sclerosis (MS), Alzheimer's Disease, Attention Deficit/Hyperactivity Disorder, obesity, bipolar disorder/mania, anxiety disorders (panic disorder with and without agoraphobia, social phobia a.k.a. Social Anxiety Disorder, Acute Stress Disorder, Generalized Anxiety Disorder), Post-traumatic Stress Disorder (one of the anxiety disorders in DSM), obsessive compulsive disorder (one of the anxiety disorders in DSM), pain (migraine, trigeminal neuralgia), chronic pain disorders (including neuropathic pain such as pain due to diabetic neuropathy, post-herpetic neuralgia, and idiopathic pain disorders such as fibromyalgia and regional myofascial pain syndromes), rehabilitation following stroke (neuro plasticity induction), tinnitus, stimulation of implanted neurons to facilitate integration, substance-related disorders (dependence and abuse and withdrawal diagnoses for alcohol, cocaine, amphetamine, caffeine, nicotine, cannabis), spinal cord injury and regeneration/rehabilitation, head injury, sleep deprivation reversal (DARPA), primary sleep disorders (primary insomnia, primary hypersomnia, circadian rhythm sleep disorder), cognitive enhancements, dementias, premenstrual dysphoric disorder (PMS), Drug delivery systems (changing the cell membrane permeability to a drug), induction of protein synthesis (induction of transcription and translation), stuttering, aphasia, dysphagia, essential tremor, Magnetic Seizure Therapy (MST), and other central nervous system disorders that may treated by the application of a magnetic field at particular locations in the brain. Of course, in each case, the treatment positions may vary; however, in each case the positioning device of the invention is useful in finding the treatment location in a repeatable manner and holding the TMS coil in the treatment position during therapy.
A perspective view of an exemplary embodiment of the positioner assembly 10 of the invention is illustrated in
In an exemplary embodiment, the chair back 14 and the front plate 16 of the coil positioner assembly 18 are at a predetermined angle such as 30°-45° to the horizontal. The actual coronal plane angle is carefully selected to facilitate patient comfort during treatment. Through experimentation, it has been found that an angle of approximately 30°-45° is desired because an angle in this range permits the patient to see around the room during treatment, thereby feeling less vulnerable, which is often an issue with patients undergoing treatment for depression, for instance. The patients also feel more comfortable because such a reclining position is similar to positions during existing TMS treatments, thereby controlling any anxiety over a new treatment apparatus. Also, the 30°-45° angle causes the majority of the weight of the patient's head to rest on the headset assembly, thereby limiting the weight on the patient's shoulders as well as slumping and fidgeting, further increasing patient comfort. Of course, those skilled in the art will appreciate that other angles for the coronal plane may be used as desired, including the horizontal position.
Once the patient is comfortably seated in the chair 12 and the chair back 14 locked in position in the coronal plane parallel to the front plate 16 of the coil positioner assembly 18, the patient's head is placed in a disposable headset assembly 32 that is removably locked into place on a headrest assembly 34 of the coil positioner assembly 18. In an exemplary embodiment, the headset assembly 32 is removably held in place in a fashion that facilitates quick release in the event that the patient needs to be quickly removed from the treatment apparatus as in an emergency or when the treatment must be paused. For example, a VELCRO™ patch 36 may be provided on the back of the headset assembly 32 as shown in
To align the patient's head in the therapy position, a disposable double-sided adhesive strip 52 of the type shown in
Once the straps 46, 48, and 50 are applied to the forehead strip 52, a sighting device or alignment guide 64 shaped like an inverted “U” is then placed over the patient's face by inserting respective ends into holders 66 on either side of the patient's head as shown in
Once the patient's head is aligned in the headset assembly 32, a stabilizer 76 (
The next step is to locate the patient's MTP using established search techniques. In accordance with the invention, the coil assembly 78 with its connector 80 is mounted in a gimbal arrangement 82 supported by an anterior/posterior adjustment post 84 that together fully support the weight of the coil assembly 78 and allow free motion in all axes. In particular, the gimbal arrangement 82 allows for adjustment of the pitch, roll and yaw of the coil assembly 78 for seating of the coil assembly 78 against the patient's head. The gimbal arrangement 82 is placed at an incline perpendicular to the coronal plane (e.g., 30°) and includes a counterbalance 86 to the coil weight (e.g., counter weights, constant force springs, adjustable force cams, and the like) to facilitate easy movement of the gimbal arrangement 82 and anterior/posterior adjustment post 84 in the anterior/posterior direction. In an exemplary embodiment, the counterbalance 86 further helps to counteract the weight of the coil assembly 78 against the patient's head, further increasing the patient's comfort during a therapy session. The gimbal arrangement 82 is further mounted on a turntable 88 that is allowed to move in a plane parallel to the coronal plane to define the angle of the left superior oblique plane projecting through the pivot axis of the patient's nose. The turntable 88 also includes counterbalances to the coil weight (e.g., counter weights, constant force springs, adjustable force cams, and the like) to facilitate easy movement of the gimbal arrangement 82 in the plane parallel to the coronal plane to define a new oblique angle position. The turntable 88 is adjusted by loosening knob 90 and swinging the turntable 88 (and hence the gimbal arrangement 82 and anterior/posterior adjustment post 84) to a different left superior oblique angle with respect to the patient's head. The turntable 88 is positioned so that its lower radial slide 92 (which is loosened to permit the coil assembly 78, gimbal arrangement 82 and anterior/posterior adjustment post to slide toward the patient's head to seat the coil assembly) is on the same plane as the estimated motor threshold position (MTP). For example, the left superior oblique angle may start at 25° and a point selected that is approximately ½ to ⅔ of the distance from the left auditory meatus (i.e. ear canal) to the vertex of the head. The MTP 94 of the patient is then determined through established search techniques by adjusting the position of the radial slide 92 to permit the coil assembly 78 to slide into contact with the patient's head and then searching in a grid about the estimated MTP. In particular, searching is conducted by adjusting the left superior oblique angle in increments by adjusting the angular position of turntable 88 and adjusting anterior (toward nose)/posterior (toward back of head) position by moving the anterior/posterior adjustment post 84 up/down in increments about the estimated MTP position. Once the coil assembly 78 is at the final MTP 94 (e.g., based on sufficient thumb twitching at a grid position found during a patterned search of a grid defined by adjustments of the angle of turntable 88 and the anterior/posterior position of anterior/posterior adjustment post 84), the turntable 88 is locked in place using knob 90 and the anterior/posterior adjustment post 84 is locked in position using knob 96, thereby locking the point of rotation of the positioner assembly 18 in the left superior oblique plane including the patient's nose, the MTP 94 and the treatment position (TXP) 98 for the case of depression treatment. The anterior/posterior setting for the anterior/posterior adjustment post 84 and the left superior oblique angle measurement from turntable 88 are then recorded on label 72 for use in subsequent treatments. The power level for the TMS measurements is also determined at the MTP 94 using known techniques.
All further coil motions will now be in the left superior oblique plane that contains the MTP 92 and the midpoint of the patient's nose. In particular, the TXP 98 for depression treatment is found by moving the coil assembly 78 forward 5 cm in the anterior direction along the oblique plane by adjusting the anterior/posterior adjustment post 84. However, those skilled in the art will appreciate that the distance of the TXP 98 from the MTP 94 may be a function of the head size of the patient. In addition, as noted above, the positioner assembly 10 of the invention could be set up to target any other anatomical landmark of the patient that also produces a repeatable position relative to internal anatomy. For example, rather than searching for the MTP 94 for use in finding a TXP 98 for treating depression, the system of the invention may be used to find the Wernicke's Area for treating schizophrenia or finding other treatment positions for other central nervous system disorders responsive to TMS treatments.
Once the TXP 98 has been found, the next step is to adjust the coil assembly 78 so that it comfortably seats against the patient's head. The gimbal assembly 78 is moved to adjust the pitch and yaw of the coil assembly 78 up against the patient's head. Such adjustments of the gimbal assembly 82 fixes the coil assembly 78 in space without affecting the point of application of the field. The roll of the coil assembly 78 also may be adjusted by turning adjustment knob 100 of the gimbal assembly 82 to adjust any roll in the coil assembly 78 that affects the seating of the coil assembly 78 against the patient's head at the TXP 98. The roll is preferably measured in degrees since a change in orientation with respect to the anatomy in the roll direction may affect the applied magnetic field depending upon the orientation of fold in the patient's brain at the TXP 98. This coil rotation (roll) setting also may be recorded on label 72 of the headset assembly 32. The coil assembly 78 is now at the TXP and ready for patient treatment.
The angular position of the turntable 88 and the anterior/posterior position of anterior/posterior adjustment post 84 are typically indicated with scales; however, the positions may also be indicated using position sensors with position feedback. Use of these measurements in subsequent therapy sessions greatly expedites set up and positioning of the patient. In addition to being recorded on label 72 of the headset assembly 32, these positions also may be automatically read and recorded in digital form using the position sensors with position feedback and the readings processed for inclusion in the patient's record. Position sensors with position feedback may be used for the other adjustments as well. Moreover, the manual adjustments may be made automatically by motor drive units. Of course, the positions also may be manually read and entered by an operator into a medical database containing the patient's medical records.
Since the procedure is highly repeatable, the recorded positions (lateral canthus position, left superior oblique angle, anterior/posterior position, and coil rotation (roll) position) in the patient's coordinates may be used to allow a patient to be treated easily on other systems that employ the same positioning and/or coordinate systems. Moreover, the disposable headset assembly 32 of the invention permits the patient to be repeatably positioned for TMS procedures or other medical procedures on the head.
The present invention is characterized by its ability to provide an alignment plane that includes, for example, the MTP, TXP and midpoint of the nose. The mechanism of the invention establishes such a plane so as to facilitate quick positioning from MTP to TXP. A cylindrical coordinate system aligned with the patient's head is used for such positioning, especially where the cylindrical axis projects through a patient landmark of interest.
Those skilled in the art also will readily appreciate that many additional modifications are possible in the exemplary embodiment without materially departing from the novel teachings and advantages of the invention. For example, the afore-mentioned constant force spring may comprise a rolled coil that applies an equal force in both movement directions to offset the weight of the coil. A pulley system may also be used as a counterweight to gravity in a known fashion.
Those skilled in the art will further appreciate that the manual mechanical adjustments of the invention may be replaced by a manual or electronic articulating arm (e.g., robotic arm) with position feedback and that the coordinates may be read and manipulated using software for recordation. In other words, the software would convert real world coordinates to the coordinate system of the patient and hold the TMS coil in position during treatment.
Also, those skilled in the art will appreciate that the gimbal assembly of the invention may be replaced by a suitable ball and socket arrangement that allows precise control of three-dimensional movements of the coil assembly.
Another significant feature of the invention is its quick release capability. The only thing holding the patient in place is the headset assembly 32, which is connected to the positioner assembly 18 by VELCRO™ and peg alignment with holes and/or slots. The headset assembly 32 thus may be easily removed from the positioner assembly 18 in the unlikely event that the patient has a seizure or treatment needs to be paused for some reason. Moreover, the patient's head may be readily removed from the headset assembly 32 by simply pulling the straps 46, 48, and 50 away from the adhesive on forehead strip 52. Alternatively, a separate headset assembly need not be required. In this case, the positioner assembly 18 could include removable conformal cushions for accepting the patient's head and adjustment straps for aligning the patient's head.
Accordingly, any such modifications are intended to be included within the scope of this invention as defined by the following exemplary claims.
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|International Classification||A61N2/02, A61G15/12, A61N2/00, A61B19/00|
|Cooperative Classification||A61N2/02, A61G15/125, A61B90/14, A61B2090/363|
|Jun 14, 2004||AS||Assignment|
Owner name: NEURONETICS, INC., PENNSYLVANIA
Free format text: ASSIGNMENT OF ASSIGNORS INTEREST;ASSIGNORS:CAMERON, ALLAN;MACNEILL, JOHN A.;FLENDER, GREG;AND OTHERS;REEL/FRAME:015453/0944;SIGNING DATES FROM 20040513 TO 20040520
|Dec 28, 2010||CC||Certificate of correction|
|Jun 26, 2013||FPAY||Fee payment|
Year of fee payment: 4
|Jul 13, 2017||FPAY||Fee payment|
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